1
Age Group Terminology
Premature Birth before 37 completed weeks gestation
Neonate 0-4 weeks
Infant 1month-1 year
Child/children 1-12 years
Adolescent 13-18 years
Adult >18 years
A-Neonatology 1-Hyperbilirubinemia in the Newbornb (Neonatal Jaundice)
Background 1-Bilirubin is derived primarily from the breakdown of heme in the
reticuloendothelial system. Nonpolar and water-insoluble unconjugated
bilirubin is conjugated inside liver cells to form Water-soluble conjugated
bilirubin (1)
.
2-Most conjugated bilirubin is excreted through the bile into the small intestine
and eliminated in the stool. Some bilirubin may undergo hydrolysis back to the
unconjugated fraction by intestinal glucuronidase, and may be reabsorbed
(enterohepatic recirculation) (2)
.
3- Nearly all newborns develop transient hyperbilirubinemia (serum bilirubin 2
mg/dL) and nearly 65% (two third) are clinically jaundiced (serum bilirubin5
mg/dL) (1)
.
4-Onset of jaundice in the first 24 hours of life is always pathological (3)
.
5-Kernicterus (Bilirubin Encephalopathy) results when indirect
(unconjugated) bilirubin is deposited in brain cells and disrupts neuronal
function (2)
. Kernicterus usually does not develop in term infants when bilirubin
levels are less than 20 to 25 mg/dL. The incidence of kernicterus increases as
serum bilirubin levels increase to greater than 25 mg/dL (2)
.
6-Kernicterus may be noted at bilirubin levels less than 20 mg/dL in the
presence of some conditions like sepsis, meningitis, and prematurity (2)
.
Unconjugated hyperbilirubinemia
1-Nonpathologic unconjugated hyperbilirubinemia
A-Physiologic Jaundice 1-Physiologic jaundice is an unconjugated hyperbilirubinemia that occurs
after the first postnatal day and can last up to 1 week. Total serum bilirubin
(TSB) concentrations peak in the first 3 to 5 postnatal days and decline to adult
values over the next several weeks (4)
.
2-The underlying mechanisms for physiologic jaundice in newborn are related
to:
2
(a) Increased bilirubin production because of elevated red blood cell
volume per body weight and a shorter and shorter life span (2, 4)
.
(b) Infants have immature hepatic glucuronosyl transferase, a key
enzyme involved in the conjugation of bilirubin (4)
.
(c) Increased enterohepatic circulation in newborn (2)
.
B-Breast milk jaundice 1-It occurs in some breast-fed infants because breast milk may contain an
inhibitor of bilirubin conjugation or may increase the enterohepatic
recirculation of bilirubin because of breast milk glucuronidase (2)
.
2-Jaundice appears in the seventh day and it gradually increased in severity
till it reaches its peak during third week (5)
. It may persists for several weeks (5)
.
3-Interruption of breast feeding and use of formula feeding for 1–3 days
causes a prompt decline in bilirubin(1)
(which do not increase significantly
after breastfeeding resumes) (2)
but is only recommended for infants with serum
bilirubin concentrations that put them at risk for kernicterus (1)
.
C-Breast feeding jaundice 1-Breastfeeding jaundice occur when a breastfeeding baby is not getting
enough breast milk , which leads to infrequent bowel movements and increased
enterohepatic circulation of bilirubin. It occurs during the first week of life) (6, 7)
.
2-Water and dextrose solutions should not be used to supplement
breastfeeding because they do not prevent hyperbilirubinemia and may lead to
hyponatremia (4)
.
D-Prematurity. 1-Although preterm infants develop hyperbilirubinemia by the same
mechanisms as term infants, it is more common and more severe in preterm
infants and lasts longer (due to the relative immaturity of the red blood cells,
hepatic cells, and gastrointestinal tract) (4)
.
2-Kernicterus is extremely uncommon. However, kernicterus in preterm infants
can occur at lower TSB concentrations (4)
. (see Kernicterus).
2-Pathologic Unconjugated Hyperbilirubinemia.
A-Acute Hemolysis: In this condition, jaundice appears at birth or during the first day and it is
commonly severe. Serum bilirubin level may rise rapidly to reach serious levels
where kernicterus may occur.
Kernicterus is a real risk and it may occur when serum bilirubin exceeds the
critical level, which depends on the birth weight and the condition of the baby.
The critical level is lower in those with low birth weight and in sick neonates (5)
.
3
The cause of haemolysis can be identified by clinical and laboratory evaluation.
1-Rh incompatibility:
It is the commonest cause of hemolysis. It occurs in some Rh
positive babies born to Rh negative mothers. Hemolysis occurs
due to placental passage of maternal antibodies active against the
fetal red cells. The first baby is usually not affected as maternal
sensitization usually occurs during delivery of the first baby (5)
.
Rh incompatibility can be prevented by injection of Rh immune
globulin to the mother within 72 hours after delivery which
prevents her from forming antibodies which might affect subsequent
babies (5)
.
2-ABO incompatibility:
ABO incompatibility may occur if the mother’s blood type is O and the
infant’s blood type is A or B (4)
. The first baby may be affected. Jaundice
is not severe. kernicterus is rare. (5)
.
B-Neonatal septicemia: 1-Jaundice in septicemia, if present, usually appears between the fourth and
seventh day or later and is usually moderate in severity (5)
.
2-The most important clinical signs are the markedly affected general
condition(The baby is not doing well with lethargy, poor suckling, fever or
hypothermia, .......). Immediate hospitalization and combined parenteral
antibiotic therapy are important (5)
.
C-Other rare causes : 1-Hemolysis Present :(e.g. -Red blood cell enzyme defects: glucose-6-
phosphate dehydrogenase) (2)
.
2- Hemolysis Absent : Mutations of glucuronyl transferase enzyme (Crigler-
Najjar syndrome, Gilbert disease), hypothyroidism (2)
.
Conjugated Hyperbilirubinemia 1-Conjugated (Direct-reacting ) hyperbilirubinemia is never physiologic and
should always be evaluated thoroughly (2)
.
2-Direct-reacting bilirubin (composed mostly of conjugated bilirubin) is not
neurotoxic to the infant, but signifies a serious underlying disorder involving
cholestasis , hepatocellular injury (2)
or biliary atresia (4)
. (atresia is an unusual
closing or absence of a tube in the body).
Therapy of Indirect (unconjugated) Hyperbilirubinemia
The main concern is to prevent Kernicterus (3)
. Charts exist indicating levels at
which treatment should be initiated.
Treatment options are: A-Phototherapy. B-Exchange transfusion (3)
.
4
Table 2 show the bilirubin level at which these treatment options indicated (8)
.
Table 2:bilirubin level at which phototherapy and exchange are indicated
Phototherapy Exchange transfusion
Healthy term
baby
Preterm or any
risk factors*
Healthy term
baby
Preterm or any
risk factors
Mg/dl μmol/l Mg/dl μmol/l Mg/dl μmol/l Mg/dl μmol/l Day 1 Any visible jaundice
** 15 260 13 220
Day 2 15 260 13 220 25 425 15 260
Day 3 18 310 16 270 30 510 20 340
Day 4 and
after 20 340 17 290 30 510 20 340
* Risk factors include small size ( less than 2.5 kg or born before 37 weeks gestation),
haemolysis, and sepsis. ** Visible jaundice anywhere on body on day 1.
A-Phototherapy 1-Blue light (not ultraviolet) of wavelength 450 nm converts the bilirubin in
the skin and superficial capillaries into harmless water-soluble metabolites,
which are excreted in urine and through the bowel (3)
.
2-The eyes are covered to prevent discomfort and additional fluids are given
to counteract increased losses from skin (3)
.
B-Exchange transfusion 1-This is required if the bilirubin rises to levels
considered dangerous despite phototherapy (3)
.
2- Twice the infant's blood volume (i.e. 2 x 80 mL/kg) is
exchanged over about 2 hours (3)
( or 2 x 85 mL/kg) (2)
.
3-The procedure is carried out through umbilical vein
catheter (9)
.
Management of conjugated
hyperbilirubinemia Management depend on the treatment of the causative diseases (if treatable e.g.
surgical correction of biliary atresia) (5)
.
References 1-Thomas P. Green. Pediatrics Just the Facts. Copyright © 2005 by..
2- Robert M. Kliegman. Nelson essentials of pediatrics. 7th edition.2015.
3- Shyam Bhakthavasala. Crash course pediatrics.3rd
edition 2008.
4- Bryon J. Lauer and Nancy D. Spector . Hyperbilirubinemia in the Newborn. Pediatrics in Review
2011;32;341
5- Mohammed El-naggar. Practical pediatric diagnosis. 5th edition. 2005.
6- Babeta A garwal. Neonatal jaundice a review. International Journal of Biomedical and Advance
Research. 2011.
7- Brooke T. Davey. Deja Review Pediatrics. Copyright © 2008.
8-Pediatrics pocket book.
9- Mohammed El-naggar. Practical pediatric therapy. 5th edition.2005.
5
2-Neonatal Sepsis and Meningitis
Background 1-Neonates, especially preterm newborns, are at increased risk for infections and
should be considered immunocompromised (1)
.
2-Risk factors of neonatal sepsis include prematurity, low birth weight, and
predisposing maternal conditions (e.g., urinary tract infection) (1)
.
3-Early-onset neonatal sepsis (sepsis that presents during the first 7 days of
life) usually is caused by organisms acquired from the maternal genital tract
(1). (see table 1)
(3).
4- Late-onset sepsis (8 to 28 days) usually occurs in a healthy full-term infant
who was discharged in good health (2)
. (see table 1) (3)
.
5-Meningitis occurs as a complication of bacterial sepsis (1)
. The major
pathogens causing neonatal sepsis are also the primary pathogens that cause
neonatal meningitis (1)
.
Table 1 (3)
Clinical Manifestations of Neonatal Sepsis 1- The most common signs are poor feeding, temperature instability
(Hypothermia is more common than fever in neonatal sepsis, especially in
preterm newborns), lethargy, or apnea (1)
.
2-Other signs of neonatal sepsis include tachycardia, dyspnea or cyanosis,
tachypnea, disseminated intravascular coagulation (DIC)and abdominal
distension (1, 6)
.
3-The clinical manifestations of sepsis are difficult to separate from the
manifestations of meningitis in the neonate (2)
.
Laboratory Diagnosis of Neonatal Sepsis A- Positive cultures of body fluids confirm the diagnosis, including the
following:
1. Blood: Must be obtained as a part of every evaluation for sepsis.
2. CSF: CSF analysis is indicated for all infants with a positive blood culture.
6
3. Urine: urine cultures are indicated, as urinary tract infections are a frequent
source of infection (4)
.
B- Hematologic studies:
1. An extremely elevated total WBC or very depressed count is more
suggestive of infection.
2. Thrombocytopenia is also associated with sepsis (4)
.
C- A chest radiograph is indicated in all infants with respiratory symptoms (4)
.
D-C-reactive protein(CRP): CRP levels are often elevated in neonatal patients
with bacterial sepsis (2)
.
E-Coagulation studies : prolonged values may indicate DIC (4)
.
Treatment of Sepsis and
Meningitis
1-The initial empiric antibiotic
treatment of choice for early-onset
neonatal sepsis and meningitis is
ampicillin plus an aminoglycoside
(Tables 2 and 3) (1)
.
[In some nurseries, a third-
generation cephalosporin (e.g.,
cefotaxime), instead of an
aminoglycoside is added to
ampicillin] (1)
.
2-If meningitis is highly suspected,
gentamicin may be replaced by a
third generation cephalosporin (cefotaxime) owing to greater CSF penetration
(1).
3-For late-onset sepsis or meningitis , a combination of vancomycin with an
aminoglycoside (gentamicin or tobramycin) is appropriate (2)
.
4-For systemic fungal infections, amphotericin B is considered the initial
treatment of choice (1)
.
Duration of therapy 1-Therapy for most bloodstream infections should be continued for a total of 7-
10 days or for at least 5-7 days after a clinical response has occurred (4)
.
2-Meningitis should be treated for 14-21 days (4)
.
Table 2
GA, gestational age; PNA, postnatal age.
7
Table 3
Supportive care 1-Fluids, electrolytes, and glucose levels should be monitored carefully with
correction when needed (5)
.
2-Seizures should be treated with anticonvulsants (5)
.
3-DIC may complicate neonatal septicemia. DIC may require fresh frozen
plasma, platelet transfusions, or whole blood (5)
.
4-The use of intravenous immunoglobulin (IVIG) has been shown to decrease
mortality in patients with sepsis (5)
.
References 1- Koda-Kimble and Young’s. Applied Therapeutics: The clinical use of drugs, 10th ed., 2013 by
Lippincott Williams & Wilkins.
2- Robert M. Kliegman. Nelson essentials of pediatrics. 7th edition.2015.
3- Andres Camacho-Gonzalez. Neonatal Infectious Diseases : Evaluation of Neonatal Sepsis. Pediatr
Clin N Am 60 (2013) 367–389.
4- Thomas P. Green. Pediatrics Just the Facts. Copyright © 2005 by The McGraw-Hill Companies,
Inc.
5- M. Kliegman. Nelson textbook of pediatrics. 19th edition.
6- Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013.
B-Nephrology 1-Nephrotic syndrome 1-Nephrotic syndrome (NS) is characterized by persistent heavy proteinuria
(mainly albuminuria) ; hypoproteinemia (serum albumin <3.0 g/dL);
hypercholesterolemia (>250 mg/dL); and edema (1)
.
8
2- Nephrotic syndrome is primarily a pediatric disorder and is 15 times more
common in children than adults (2)
with a peak age of onset in children aged
<6yrs (3)
.
3-The underlying abnormality in nephrotic syndrome is an increase in
permeability of the glomerular capillary wall, which leads to massive
proteinuria and hypoalbuminemia (2)
.
4-Hypoalbuminemia causes a decrease in the plasma oncotic pressure and shift
of fluid from the intravascular compartment to the interstitial space. Reduced
plasma volume stimulates antidiuretic hormone (ADH) secretion and the renin–
angiotensin system, producing sodium and water retention, exacerbating the
edema (2, 4)
.
Classification: Approximately 90% of children with NS have idiopathic NS. Idiopathic NS
includes three histologic types (2)
:
A-Minimal change nephrotic syndrome (MCNS) is the most common form of
NS in children (accounts for about 85%) (1, 2)
.
2-Other less common types are [Focal segmental glomerulosclerosis (FSGS),
and Membranoproliferative glomerulonephritis (MPGN) ] (1)
.
Clinical features 1-Children usually present with mild edema, which is initially noted around the
eyes (Periorbital ) and in the lower extremities (2)
. Periorbital oedema is often
most noticeable in morning on rising (3)
.
2-With time, the edema becomes generalized, with the development of ascites,
pleural effusions, and genital edema (2)
.
Treatment 1-NS edema is treated by restricting salt intake. Severe edema may require the
use of loop diuretics. When these therapies do not alleviate severe edema,
parenteral administration of 25% albumin (0.5 to 1.0 g/kg intravenously over 1
to 2 hours) with an intravenous loop diuretic usually results in diuresis (1)
.
2-Children with onset of nephrotic syndrome between 1 and 8 yr of age are
likely to have steroid-responsive minimal change disease, therefore, steroid
therapy (prednisolone 2 mg/kg/day)( 60 mg/m2/day) may be initiated without
renal biopsy (2)
.
3-After the initial 4-6 wk course, the prednisone dose should be tapered to 40
mg/m2/day given every other day as a single morning dose. The alternate-day
dose is then slowly tapered and discontinued over the next 2-3 mo (2)
.
9
4-Steroid-dependent patients (relapse while on alternate-day steroid therapy or
within 28 days of stopping prednisone therapy), frequent relapsers, and
steroid- resistant patients may be candidates for alternative agents (e.g.
Cyclophosphamide) (2)
.
5-Acute hypertension (HTN) is treated with β-blockers or calcium channel
blockers. Persistent HTN usually responds to ACE inhibitors (1)
.
6-ACE inhibitors and angiotensin II blockers may be helpful as an adjunct
therapy to reduce proteinuria in steroid-resistant patients (2)
.
Complications 1-Infection is the major complication of nephrotic syndrome. Children in
relapse have increased susceptibility to bacterial infections owing to urinary
losses of immunoglobulins and use of immunosuppressive therapy. Spontaneous
bacterial peritonitis is the most frequent type of infection (2)
.
2-The role of prophylactic antibiotic therapy during relapse remains
controversial (2)
.
3-Children with nephrotic syndrome are also at increased risk for
Thromboembolism (TE). (related to increased prothrombotic factors (e.g.
fibrinogen,) and decreased fibrinolytic factors) . Prophylactic anticoagulation
is not recommended in children unless they have had a previous TE.
Warfarin, low-dose aspirin, or dipyridamole may minimize the risk of clots in
NS patients with a history of TE or high risk for TE (1, 2)
.
Prognosis 1-The majority of children with steroid-responsive NS have repeated relapses,
which generally decrease in frequency as the child grows older (2)
.
2-Steroid-responsive patients have little risk of chronic renal failure (1)
.
3-Children with steroid-resistant NS, most often caused by focal segmental
glomerulosclerosis, generally have a much poorer prognosis. These children
develop progressive renal insufficiency, ultimately leading to end-stage renal
failure requiring dialysis or renal transplantation (2)
.
References 1-Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition.2015.
2-Nelson Textbook of pediatrics. 29th edition.
3-Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013
4-Nandu Thalange. Essential of pediatrics. Second Edition. 2013.
2-Hemolytic-Uremic Syndrome
1-The hemolytic-uremic syndrome (HUS) is the most common cause of acute
renal failure in young children and is characterized by hemolytic anemia,
thrombocytopenia, and uremia (1)
.
10
2- HUS typically occurs in children less than 5 years of age but can occur in
older children (2)
.
3-Two forms of HUS are recognized.
A-Diarrhoea-associated (D+ HUS): most commonly caused by toxin-
producing Escherichia coli (0157:H7).
B- Not diarrhoea-associated (D– HUS)
(3).
Clinical Manifestations.
1-Classic D+HUS begins with gastroenteritis characterized by fever, vomiting,
and diarrhea that is often bloody. Followed in 7 to 10 days by weakness,
lethargy, and oliguria/anuria. Physical examination reveals irritability,pallor, and
petechiae (1, 2)
.
Treatment and Prognosis 1-Therapy for HUS is supportive and includes volume repletion, and
managing complications of renal insufficiency, including dialysis when
indicated (2)
.
2-Red blood cell transfusions are provided as needed (2)
.
3-Antibiotics and antidiarrheal agents may increase the risk of developing
HUS (2)
. [Antibiotics should be avoided in patients with acute enteritis presumed
secondary to E. coli 0157:H7 as they may increase the risk of developing HUS.
4-Most children (>95%) with D+HUS survive the acute phase and recover
normal renal function, although some may have evidence of long-term
morbidity (2)
.
References 1-Nelson Textbook of pediatrics. 29
th edition.
2-Robert M. Kliegman. Nelson essentials of pediatrics. 7th edition. 2015.
3-Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013.
C-Infections 1-Bronchiolitis
1-Bronchiolitis, a lower respiratory tract infection (LRTI) that primarily affects
the small airways (bronchioles), is a common cause of illness and hospitalization
in infants and young children (1)
.
2-Bronchiolitis is seasonal, with peak activity during winter and early spring (2)
.
3-Bronchiolitis occurs almost exclusively during the first 2 years of life, with a
peak age at 2 to 6 months (3)
.
4- Acute bronchiolitis is characterized by bronchiolar obstruction with edema,
mucus, and cellular debris (2)
.
11
Etiology 1-Acute bronchiolitis is predominantly a viral disease. Respiratory syncytial
virus (RSV) is responsible for more than 50% of cases (2)
.
2-Other agents include parainfluenza, adenovirus, Mycoplasma, and
occasionally other viruses (2)
.
Clinical Manifestations. 1-The infant first develops a mild upper respiratory tract infection with sneezing
and clear rhinorrhea. This may be accompanied by diminished appetite and
fever (2)
.
2-Gradually, respiratory distress ensues, with paroxysmal wheezy cough,
dyspnea, and irritability. The infant is often tachypneic, which interferes with
feeding (2)
.
3-As a result of limited oral intake due to coughing combined with fever, infants
are frequently dehydrated (6)
.
Diagnosis
The diagnosis of bronchiolitis is based primarily on history and clinical
findings (6)
.
Treatment
1-The mainstay of treatment is supportive. Therapy of bronchiolitis primarily
consists of administration of supplemental oxygen and replacement of fluid
deficits (hydration) as needed (2, 4 )
.
2-The risk of aspiration of oral feedings may be high in infants with
bronchiolitis owing to tachypnea and the increased work of breathing. The
infant may be fed through a nasogastric tube (2)
.
3-A number of agents have been proposed as adjunctive therapies for
bronchiolitis:
A-Bronchodilators produce modest short-term improvement in clinical
features. Nebulized epinephrine may be more effective than β-agonists (2)
.
B-Corticosteroids, whether parenteral, oral, or inhaled, are widely used
despite conflicting studies (2)
.
C-Ribavirin, is a compound with antiviral activity against RSV administered
by aerosol, has been used for infants with congenital heart disease (CHD)or
chronic lung disease (CLD) (2, 4)
although its benefit is uncertain (5)
.
D-Antibiotics have no value unless there is secondary bacterial pneumonia (2)
.
12
Prophylaxis
1-Palivizumab is a monoclonal antibody to RSV and can be used as prophylaxis (5)
initiated just before the onset of the RSV season (monthly IM injection for
5months starting in October) confers some protection from severe RSV disease (3, 5)
2-Palivizumab is indicated for some infants under 2 years old with CLD, severe
CHD or prematurity (2, 3)
.
References 1-Pedro A Piedra. Bronchiolitis in infants and children: Clinical features and diagnosis. Uptodate.19.3.
2-Nelson Textbook of pediatrics. 29th edition.
3-Robert M. Kliegman. Nelson essentials of pediatrics. 7th edition. 2015.
4-Edward T. Bope, et al, eds. Conn’s Current Therapy. Copyright 2013.
5-Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013
6-Joseph T. DiPiro, Robert L. Pharmacotherapy: A Pathophysiologic Approach, 8th Edition.
Copyright
2-Pneumonia 1-Pneumonia is defined as infection of the lung parenchyma (that is of the
alveoli rather than the bronchi or bronchioles) and characterized by
consolidation (1)
.
(Consolidation is a pathological process in which the alveoli are filled with a mixture of
inflammatory exudate, bacteria and WBCs that on chest X-ray appear as an opaque shadow in
the normally clear lungs) (1)
.
Etiology Viruses alone account for 14–35% of all community acquired pneumonia in
childhood (2)
.
M. pneumoniae and Chlamydophila pneumoniae are principal causes of atypical
pneumonia (3)
. Common infecting bacterial agents by age are [ ليست للحفظ ] (2) :
1-Neonates: group B streptococcus, Escherichia coli, Klebsiella,
Staphylococcus aureus.
2-Infants: Streptoccus pneumoniae, Chlamydia.
3-School age: Streptococcus pneumoniae, Staphylococcus aureus, group A
streptococcus, Bordetella pertussis, Mycoplasma pneumoniae.
Clinical Manifestations In many cases these symptoms are preceded by minor upper respiratory tract
infection symptoms. The patient may also be complaining of pleuritic chest pain
or abdominal pain. The typical history will have:
• Temperature > 38.5 0C;
• Tachypnea and Shortness of breath;
• Cough; [with sputum production in older children (>7yrs)] (2, 4)
.
Diagnosis • Diagnosis of pneumonia in many cases is made based on the presence of
clinical signs and symptoms.
13
• Chest x-ray are often used to confirm the diagnosis (4)
.
Treatment (2).
1-Oral antibiotics are safe and effective in the treatment of community acquired
pneumonia. IV antibiotics are used in children who cannot absorb oral
antibiotics or in those with severe symptoms.
2-Supportive therapies Consider whether any of the following are needed:
• Antipyretics for fever.
• IV fluids: consider if dehydrated or not drinking.
• Supplemental oxygen.
Complications 1-Bacterial pneumonias frequently cause inflammatory fluid to collect in the
adjacent pleural space, causing an empyema [empyema is collection of pus in a
cavity, especially in the pleural cavity] . Small empyema may not require any
special therapy. Large empyema may restrict breathing and require
drainage (3)
.
References 1-Roger Walker, Clive Edwards (eds), Clinical Pharmacy and Therapeutics, 5th Ed.,
Churchill Livingstone, London, 2012.
2- Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013.
3-Robert M. Kliegman. Nelson essentials of pediatrics. 7th edition. 2015.
4-Thomas P. Green. Pediatrics Just the Facts. Copyright © 2005.
14
3-Meningitis 1-Meningitis is an inflammation of the membranes (the meninges), whereas
encephalitis is an inflammation of the brain tissue (1)
. 75% of cases of
meningitis are believed to occur in those <15yrs of age (2)
.
2-Three organisms (Streptococcus pneumoniae, Neisseria meningitides and
Haemophilus influenzae type b) account for 80% of the cases (2)
. [In newborns,
Group B streptococcus , E. coli, and Listeria monocytogenes are the most
common pathogens] (3)
.
Clinical Manifestations (2, 4).
1- In young infants symptoms may be non-specific including fever, poor
feeding, lethargy.
2-In older children clinical features include:
• General: fever, with headache.
• Central: irritability, disorientation, altered mental state.
• Seizures: occur in 30%.
• Neck stiffness: more common in older children.
• Kernig and Brudzinski signs of meningeal irritation are often positive in
children older than 12 months.
Diagnosis 1-If bacterial meningitis is suspected, a lumbar puncture should be performed .
Routine CSF examination includes a white blood cell count, differential, protein
and glucose levels, and Gram stain (4)
.
Treatment 1-Treatment of bacterial meningitis focuses on sterilization of the CSF by
antibiotics (Table 1) (4)
.
2-Duration of treatment is 5 to 7 days for N. meningitidis, 7 to 10 days for H.
influenzae, and 10 to 14 days for S. pneumoniae (4)
.
3-Steroids In bacterial meningitis: • Do not use corticosteroids in children younger than 3mths
(2).
• There is benefit from the use of dexamethasone and the dosing schedule is
0.15mg/kg qds for 4 days to reduce the severity of neurological sequelae,
particularly deafness, after bacterial meningitis) (2)
.
• If dexamethasone was not given before the first dose of antibiotics, but was
indicated, try to give the first dose within 4hr of starting antibiotics, but do not
start dexamethasone more than 12 hours after starting antibiotics (2)
.
15
Table 1: Initial Antimicrobial Therapy by Age for Presumed Bacterial
Meningitis
References 1-Marie A. Chisholm-Burns .Pharmacotherapy Principles & Practice Copyright © 2008 by The
McGraw-Hill Companies.
2- Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013.
3-Thomas P. Green. Pediatrics Just the Facts. Copyright © 2005 by The McGraw-Hill Companies,
Inc.
4-Robert M. Kliegman. Nelson essentials of pediatrics. 7th edition. 2015.
4-Encephalitis 1-Encephalitis is an inflammation of the brain tissue . Viruses are the
principal causes of acute infectious encephalitis (1)
.
Clinical Manifestations 1-Acute infectious encephalitis usually is preceded by a prodrome of several
days of nonspecific symptoms such as sore throat, fever, and headache followed
by the characteristic symptoms of progressive lethargy, behavioral changes,
and neurologic deficits. Seizures are common at presentation (1)
.
Diagnosis
The diagnosis of viral encephalitis is supported by examination of the CSF (1)
.
Treatment
1-With the exception of HSV, varicella-zoster virus, cytomegalovirus, and HIV,
there is no specific therapy for viral encephalitis. Management is supportive (1)
.
16
2-Intravenous acyclovir is the treatment of choice for HSV and varicella-
zoster virus infections. Cytomegalovirus infection is treated with ganciclovir.
HIV infections may be treated with a combination of antiretroviral agents (1)
.
References 1-Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition. 2015.
5-Visceral Leishmaniasis (Kala-azar) (Black fever)(1, 2)
1-Visceral Leishmaniasis (VL) is caused by the protozoon Leishmania
donovani.
2- Infection are introduced by the feeding female sand fly.
3- The great majority of people infected remain asymptomatic. In visceral
diseases the spleen, liver, bone marrow and lymph nodes are primarily involved.
Clinical features 1-VL is predominantly a disease of small children and infants.
2-The first sign of infection is high fever, usually accompanied by rigor and
chills.
3-Splenomegaly develops quickly in the first few weeks and becomes massive
as the disease progresses. Moderate hepatomegaly occurs later.
Lymphadenopathy may also seen .
4-Blackish discoloration of the skin, from which the disease derived its name,
kala-azar (the Hindi word for ‘black fever’), is a feature of advanced illness and
is now rarely seen.
5-Pancytopenia is a common feature.
6-Without adequate treatment most patients with clinical VL die.
Diagnosis 1-Demonstration of amastigotes in splenic smears is the most efficient means of
diagnosis, with 98% sensitivity ; however, it carries a risk of serious
haemorrhage in inexperienced hands.
2-Serodiagnosis, by ELISA or indirect immunofluorescence antibody test
(IFAT). A significant proportion of the healthy population in an endemic region
will be positive for these tests due to past exposure.
Treatment 1- The pentavalent antimony compound [sodium stibogluconate
(Pentostam®)]. The daily dose is 20 mg/kg body weight, given either
intravenously or intramuscularly for 28 days.
17
2-Side-effects are common and include arthralgias, myalgias, raised hepatic
transaminases, pancreatitis and ECG changes.
3-Amphotericin B is very useful in the treatment of antimony-unresponsive VL
References 1- Nelson Textbook of pediatrics. 29
th edition.
2- Nicholas A. Boon, Nicki R. Colledge and Brian R. Walker. Davidson's Principles and Pracrtice of
Medicines . 21st Edition 2010.
6-Cytomegalovirus (1-3)
. 1- Cytomegalovirus (CMV) is the most common congenital infection and the
leading cause of hearing loss, mental retardation, retinal disease, and cerebral
palsy.
2-Transmission occurs transplacentally or perinatally through contact with
cervical secretions or through breast milk. Perinatal exposure is not usually
associated with disease in term infants, but preterm infants may be infected.
3-When primary infection occurs in mothers during a pregnancy, the virus is
transmitted to the fetus in approximately 35% of cases.
4-The earlier in gestation that the primary maternal infection occurs, the more
symptomatic the infant will be at birth.
Presentation 1-More than 90% of infants who have congenital CMV infection exhibit no
clinical evidence of disease at birth.
2-Approximately 10% of infected infants are small for gestational age and have
symptoms at birth. The characteristic signs and symptoms include:
Intrauterine growth retardation, prematurity, hepatosplenomegaly and
jaundice, thrombocytopenia and purpura, microcephaly (small head)and
intracranial calcifications. Other neurologic problems include retinitis, and
hearing abnormalities.
3-Mortality is 10% to 15% in symptomatic newborns.
4-In case of perinatal CMV infection acquired during birth or from mother’s
milk, the majority of infants remain asymptomatic and do not exhibit sequelae.
Diagnosis. 1-Congenital CMV infection is diagnosed by detection of virus in the urine or
saliva.
2- Positive CMV immunoglobulin M (IgM) serology is highly suggestive, but
NOT diagnostic.
18
Treatment
1-There are limited options for treatment of CMV infection. Treatment is not
indicated for immunocompetent persons, but is recommended for
immunocompromised persons, and remains controversial for infants with
symptomatic congenital infection.
2-Treatment of Congenital Infection: Trial studies in severely symptomatic
newborns of the antiviral agent ganciclovir have shown a lack of progression of
hearing loss.
Dose: 6 mg/kg I.V every 12 hours for 6 weeks.
3-Ganciclovir is related to aciclovir but it is more active against
cytomegalovirus; it is also much more toxic (Myelosuppression) than
aciclovir.
References 1- Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition. 2015.
2- Nelson Textbook of pediatrics. 29th edition.
3-Thomas P. Green. Pediatrics Just the Facts. Copyright © 2005 by .
D-Neurology 1-Guillain–Barré syndrome (1-3)
. 1-Guillain-Barré syndrome (GBS): is a postinfectious autoimmune peripheral
neuropathy that can occur about 10 days after a respiratory or
gastrointestinal infection (bacterial or viral).
2-It occurs in people of all ages and is the most common cause of acute flaccid
paralysis in children.
Clinical Manifestations 1-The characteristic symptoms are flaccidity, and symmetrical ascending
weakness.
2-Ascending weakness: Weakness begins usually in the lower extremities and
progressively involves the trunk, the upper limbs, and finally the bulbar muscles
((tongue, pharynx, larynx).
3-Respiratory insufficiency may result.
4-Recovery: should begin within 2–4wks, in a descending manner, though full
recovery sometimes takes a number of months.
Diagnosis
The main diagnostic features of GBS is clinical( muscle weakness, with loss
of reflexes in an ascending fashion).
19
Prognosis 1-The clinical course is usually benign, and spontaneous recovery begins
within 2-3 wk. Most patients regain full muscular strength, although some are
left with residual weakness.
2-Bulbar and respiratory muscle involvement may lead to death if the syndrome
is not recognized and treated.
Treatment 1-Intravenous immunoglobulin (IVIG)(400mg/kg/day for 5 days) is normally
used initially.
2-Plasmapheresis and immunosuppressive drugs are alternatives when IVIG
treatment is unsuccessful.
References 1- Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition. 2015.
2- Nelson Textbook of pediatrics. 29th edition.
3- Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013.
2-Cerebral palsy (CP) (1-4).
Definition: a chronic disorder of movement and/or posture that presents early
(i.e. before the age of 2yrs) and continues throughout life.
Causation: CP is caused by nonprogressive (static) injury to the developing
brain (1)
.
Causes of CP
The cause is unknown in many patients but identified risk factors can be
categorized into antenatal, intrapartum, and postnatal:
A-Antenatal: congenital infections(
rubella, cytomegalovirus,
toxoplasmosis).
B-Intrapartum: birth asphyxia.
C-Postnatal: (hyperbilirubinemia,
hypoglycemia, meningitis,
encephalitis,….).
Clinical features CP can present with:
1-Delayed motor milestones : Most children with CP, except in its mildest
forms, are diagnosed in the first 18 months of life when they fail to attain motor
milestones.
2-Feeding difficulties due to lack of oromotor coordination.
3-Speech and language delay.
20
Classification 1-CP classified into 4 types (Spastic CP, Ataxic CP, Dyskinetic CP, and Mixed
CP).
2-Spastic CP the most common form of CP, it accounts for 70%–80% of
cases. It can be hemiplegic (affects one side of the body), diplegic (affects legs
or arms), or quadriplegic (affects all the four limbs).
Problems associated with CP 1-Mental retardation and learning difficulty.
2-seziures
3-gastro-esophageal reflux
4-feeding problems and failure to thrive (FTT).
5-Recurrent pneumonia.
6-hearing and vision abnormalities.
Diagnosis The diagnosis is made on clinical examination. An MRI scan of the brain is
generally indicated to determine the location and extent of lesions .
Treatment. 1-Treatment of CP required multidisciplinary approach including (Speech,
physiotherapy, and occupational therapy ).The primary therapists are the child’s
carers.
2-Several drugs have been used to treat spasticity, including dantrolene
sodium, the benzodiazepines, and baclofen. These medications should be
considered if severe spasticity is not controlled by other measures.
3-Patients with rigidity, and spastic quadriparesis sometimes respond to
levodopa.
References 1- Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition. 2015.
2- Nelson Textbook of pediatrics. 29th edition.
3- Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013
4- Shyam Bhakthavasala. Crash course pediatrics.3rd
edition 2008.
3-Febrile convulsion 1-A febrile convulsion is a fit occurring in a child (generally between the ages
of 6mths and 6yrs), precipitated by fever ( temp > 38 C) arising from
infection outside the nervous system in a child who is otherwise neurologically
normal (1-3)
and in case of absence of acute electrolyte imbalance (4)
.
2-They occur in up to 4% of all children . The vast majority of febrile seizures
are harmless (3)
.
21
3-Children prone to febrile seizures are not considered to have epilepsy ( 95–
98% of children who have experienced febrile seizures do not go on to develop
epilepsy) (3)
.
Etiology 1-The etiology is unknown. Genetic predisposition appear to be a risk factor
(1,2)
2-Typically febrile seizure occurs within the 1st 24 hour of a febrile episodes (1)
and most commonly due to acute viral respiratory infections (5)
.
Types of febrile seizure 1-Simple febrile seizures last less than 15 minutes, and occur only once in a
24-hour period (6)
. The risk of subsequent epilepsy is not substantially greater
than that for the general population (6)
.
2-If the seizure lasts longer than 15 minutes or recurs within 24 hours the
seizure is referred to as a complex or atypical febrile seizure (6)
. It signify a
greater risk of later epilepsy (1,4)
.
Diagnosis: Diagnosis is made by exclusion of other causes of symptomatic seizures like
meningitis or metabolic abnormalities (4)
.
Treatment 1-Control fever : Measures to reduce elevated temperature should be initiated.
Acetaminophen (or ibuprofen) and tepid sponge baths usually are helpful (1)
.
However, administration of antipyretics during febrile illnesses does not
prevent febrile seizures (6)
.
2-Febrile seizures always are outgrown (7)
, so typically, Long-term treatment
or prophylaxis with antiepileptic drug (AED) for simple febrile seizures is
not recommended (1)
.
3-Oral diazepam (Valium) prophylaxis, started at the onset of fever, prevents
febrile seizure (7)
( oral diazepam, 0.3 mg/kg q8h , is administered for the
duration of the illness (usually 2-3 days). This strategy may be useful when
parental anxiety associated with febrile seizures is severe (8)
.
4-Patients who have prolonged febrile seizures can benefit from rectal
diazepam gel given soon after the onset of a febrile seizure to prevent additional
prolonged seizures (7)
.
Reference: 1-Koda-Kimble and Young’s. Applied Therapeutics: The clinical use of drugs, 10th ed., 2013 by
Lippincott Williams & Wilkins.
2-Bernard Valman, ABC of first year, 5th edition, 2002.
3-Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd edition.2013.
4-Current Pedaitric therapy, 18th edition, 2006.
5-Judith M. Sondheimer, Current essentials of Pediatrics, 2008
22
6-Robert M. Kliegman. Nelson essentials of pediatrics. 7th edition. 2015.
7-Edward T. Bope, et al, eds. Conn’s Current Therapy. Copyright 2014.
8-Nelson Textbook of pediatrics. 29th edition.
E-Rheumatic Diseases of Childhood 1- Kawasaki disease (KD)
(1-4)
1-Kawasaki disease (KD) is a systemic vasculitis of unknown etiology . KD
most commonly occurs in children younger than 5 years of age, with a peak
between 2 to 3 years.
2-The etiology is unknown but the disease process is a vasculitis affecting small
to medium-sized arteries including the most importantly the coronary
arteries leading to coronary artery aneurysms.
3-Subsequent scar formation causes vessel narrowing , myocardial ischemia or
even infarction and sometimes sudden death.
Clinical Manifestations and diagnosis 1-The diagnosis can be made in children with fever present for at least 5 days,
without other explanation, in the presence of 4 of the 5 following criteria
A- Bilateral conjunctival injection.
B- Changes in the mucosa of the oropharynx including dry fissured lips,
and strawberry tongue.
C- Changes of the peripheral extremities, such as edema and/or erythema
of the hands or feet.
D- Skin rash.
E-Cervical adenopathy.
Treatment 1-Intravenous immunoglobulin (IVIG) is the mainstay of therapy for KD,
although the mechanism of action is unknown. A single dose of IVIG (2 g/kg
over 12 hours) results in rapid resolution of clinical illness in most patients and,
more important, reduces the incidence of coronary artery aneurysms.
2-Aspirin is initially given in anti-inflammatory doses (80 to 100 mg/kg/day
divided every 6 hours) . Once the fever resolves, aspirin is reduced to
antithrombotic doses (3 to 5 mg/kg/day as a single dose) (there is an increased
coagulability) and usually given for 6 to 8 weeks, until follow-up
echocardiography documents the absence or resolution of coronary artery
aneurysms.
References 1- Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition. 2015.
2- Nelson Textbook of pediatrics. 29th edition.
3- Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013
4- Shyam Bhakthavasala. Crash course pediatrics.3rd
edition 2008.
23
F-Cardiovascular Disorders
1-Acute rheumatic fever 1-Acute rheumatic fever remains an important preventable cause of cardiac
disease (1)
. Acute rheumatic fever usually affects children (most commonly
between 5 and 15 years) or young adults (2)
.
2-The condition is triggered by an immune-mediated response to infection
with specific strains of group A streptococci, which have antigens that may
cross-react with cardiac myosin and membrane protein. Antibodies produced
against the streptococcal antigens cause inflammation in the heart as well as
the joints and skin (2)
.
Clinical features
1-Acute rheumatic
fever is a multisystem
disorder that usually
presents with fever,
and joint pain, 2–6
weeks after an
episode of
streptococcal
pharyngitis (1, 2)
.
2-The presence of
either two major
criteria or one major
and two minor
criteria, along with evidence of preceding streptococcal infection, confirm a
diagnosis of acute rheumatic fever (1)
.
[Streptococcal antibody tests, such as the antistreptolysin O (ASO) titer, are the
most reliable laboratory evidence of prior infection] (1)
.
Management of the acute attack
1-A single dose of benzyl penicillin 1.2 million U i.m. or oral phenoxymethyl
penicillin for 10 days should be given on diagnosis to eliminate any residual
streptococcal infection. If the patient is penicillin-allergic, erythromycin or a
cephalosporin can be used (2)
.
2-Bed rest is important, as it lessens joint pain and reduces cardiac workload (2)
.
3-Aspirin: This will usually relieve the symptoms of arthritis rapidly (2)
. The
usual dose of aspirin is 100 mg/kg/24 hr divided qid PO for 3-5 days, followed
by 75 mg/kg/24 hr divided qid PO for 4 wk (3)
.
4-Patients with carditis and cardiomegaly or congestive heart failure should
receive corticosteroids.
Table 1: criteria for the diagnosis of rheumatic fever (2)
.
24
The usual dose of prednisone is 2 mg/kg/24 hr in 4 divided doses for 2-3 wk
followed by a tapering of the dose that reduces the dose by 5 mg/24 hr every 2-3
days (3)
.
5-Supportive therapies for patients with moderate-to-severe carditis include
digoxin, fluid and salt restriction, diuretics, and oxygen (3)
.
6-Sedatives may be helpful early in the course of chorea; Phenobarbital is the
drug of choice. If phenobarbital is ineffective, then haloperidol or
chlorpromazine should be initiated (3)
.
Secondary prevention
1-Patients are susceptible to further attacks of rheumatic fever if another
streptococcal infection occurs, and long-term prophylaxis with penicillin should
be given as i.m benzathine penicillin monthly (2)
.
2-Further attacks of rheumatic fever are unusual after the age of 21, when
treatment may be stopped (2)
.
Chronic rheumatic heart disease
Chronic valvular heart disease develops in at least half of those affected by
rheumatic fever with carditis (2)
. This result in scarring and fibrosis of the heart
valves (most commonly mitral valve) and may result in incompetent valves
requiring replacement (4)
.
References 1- Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition. 2015.
2- Nicholas A. Boon, Nicki R. Colledge and Brian R. Walker. Davidson's Principles and Pracrtice
of Medicines . 21st Edition 2010.
3- Nelson Textbook of pediatrics. 29th edition.
4- Robert C. Tasker. Oxford Handbook of Paediatrics.
2nd
edition.2013.
2-Congenital Heart Disease
A-Ventricular Septal Defect (VSD) VSD is the most common congenital heart
defect accounts for 25% of all congenital
heart disease (1)
.
Clinical Manifestations Small VSDs with little are often
asymptomatic. Moderate to large VSDs result
in excessive pulmonary blood flow ,
pulmonary hypertension and heart failure (1,
2).
Small VSD 1-The child is asymptomatic
(3).
25
2-Antibiotic prophylaxis against bacterial endocarditis should be provided
for dental visits (including cleanings) (2, 3)
.
3-Spontaneous closure might occur (3)
.
Medium VSD 1-These usually present with symptoms during infancy including slow weight
gain, feeding difficulties, and recurrent chest infections (3)
.
2-Heart failure, if present, should be treated by diuretics (± digoxin) and
ACE inhibitors (1, 3)
.
3-Spontaneous improvement occurs in many childhood cases and surgical
correction can be avoided. However, if there significant VSD at 4 years, closure
should be considered before the child starts school (3)
.
Large VSD Heart failure develops early on. Initial treatment of heart failure is required and
surgical closure is usually necessary (3)
.
References 1-Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition. 2015.
2-M. Kliegman. Nelson textbook of pediatrics. 19th edition.
3-Shyam Bhakthavasala. Crash course pediatrics.3rd
edition 2008.
B-Atrial Septal Defect (ASD) 1-Atrial septal defects are common, representing 5–10% of
all congenital heart defects (1)
.
2-Children with an atrial septal defect are asymptomatic (1)
.
3-While patients with ASD are asymptomatic in childhood,
problems with congestive heart failure, and pulmonary
hypertension can develop in the third decade of life and
beyond (1)
.
4-Treatment: ASD closure is required and advised for all
patients, even if asymptomatic. Intervention should be
performed in early childhood, before school entry (2)
.
References 1-Thomas P. Green. Pediatrics Just the Facts. Copyright © 2005 by The McGraw-Hill Companies.
2-Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013
G-Gastroenterology 1-Acute Gastroenteritis (GE) It is an infection of the small intestine, which present with a combination of
diarrhea and vomiting (1)
, but sometimes present without vomiting (2)
.
26
Etiology 1-Rota virus is the most common pathogen in children under 2 years
(3), other
causes include:
A-Acute bacterial infections (shigellae, Salmonellae, E coli and Vibirio cholera
which secrete enterotoxins) (3)
.
B-Parasites like E. histolytica, and Giardia lambilia (2)
.
Clinical Features 1-Rotaviruse cause watery diarrhea . Respiratory illness occur in about half
of patients followed by vomiting and diarrhea (1, 2)
.
2-Acute bacterial infection cause invasion of GIT, so there is fever, and small
volume bloody stool (3)
.
Complication of Gastroenteritis Dehydration, metabolic disturbances and even death
(4).
Treatment 1-Uncomplicated viral GE requires no specific treatment except attention to
fluid and electrolyte replacement (3)
Most of these episodes are self-limited (4)
.
2-There is no role for antiemetic or antidiarrheal in GE (1)
.
3-Antibiotics are rarely indicated except for specific infections such as
invasive salmonellosis, cholera , amebiasis or giardiasis (1, 3)
.
4-The key management of GE is rehydration with correction of fluid and
electrolyte imbalance (1)
.
A-Unless the child has persistent vomiting,oral fluid is the best means for
rehydration, smaller more frequent sips may be better tolerated and should
be encouraged (1)
.
B-Mild Dehydration: ORS are used (1)
.
C-Moderate dehydration: Oral rehydration is still indicated if tolerated.
D-I.V fluid should be reserved for those with vomiting or severe
dehydration (1)
.
5-Zinc supplementation (10–20 mg for 10–14 days) has been recommended by
the WHO for the treatment and prevention of diarrheal disease in children in
developing countries (4)
.
6-Continuation of oral feeding, despite diarrheal episodes, decreases the
duration of illness; and improves nutritional status (4)
.
27
Reference 1- Shyam Bhakthavasala. Crash course pediatrics.3
rd edition 2008.
2- Bernard Valman. ABC of first year, 5th edition, 2002.
3- Judith M. Sondheimer, MD. Current Essentials Pediatrics. Copyright © 2008 by The McGraw-
Hill Companies, Inc.
4- Koda-Kimble and Young’s. Applied Therapeutics: The clinical use of drugs, 10th ed., 2013 by
Lippincott Williams & Wilkins.
2-Viral Hepatitis
Etiology 1-There are six primary hepatitis viruses: Hepatitis A virus (HAV), Hepatitis B
virus (HBV), Hepatitis C virus (HCV), Hepatitis D virus (HDV), Hepatitis E
virus (HEV) and Hepatitis G virus (HGV) (1)
.
2-They differ in their transmission, severity, likelihood of persistence, and
subsequent risk of hepatocellular carcinoma (1)
.
HAV HBV HCV HDV HEV HGV
Transmission Fecal
-oral
Transfusion
, sexual,
perinatal
Parenteral,
transfusion,
perinatal
Similar
to HBV
Fecal
-oral
Parenteral,
transfusion
Note - The most important risk factor for acquisition of HBV in children is
perinatal exposure to infected mother. In most cases, transmission occurred
at the time of delivery; virus contained in amniotic fluid or in maternal blood
may be the source. However less commonly intrauterine infection occurred (2)
.
3-HBV and HCV cause chronic infection, which may lead to cirrhosis and is
a significant risk factor for hepatocellular carcinoma (1)
.
Clinical Manifestations 1-Asymptomatic or mild, nonspecific illness without icterus (jaundice) is
common with HAV, HBV, and HCV, especially in young children(1)
.
2-The preicteric phase, which lasts approximately 1 week, is characterized by
headache, anorexia, malaise, abdominal discomfort, nausea, and vomiting and
usually precedes the onset of clinically detectable disease (1)
.
3-Jaundice and tender hepatomegaly are the most common physical findings
and are characteristic of the icteric phase. Hepatic enzymes may increase 15- to
20-fold (1)
.
4-Resolution of the hyperbilirubinemia and normalization of the transaminases
may take 6 to 8 weeks (1)
.
28
Complications 1-Most cases of acute viral hepatitis resolve without specific therapy, with less
than 0.1% of cases progressing to fulminant hepatic necrosis which is
associated with a high mortality rate (1)
.
2-HAV and HEV cause acute infection only. HBV, HCV, and HDV may
persist as chronic infection with chronic inflammation, fibrosis, and cirrhosis
and the associated risk of hepatocellular carcinoma (1)
.
Diagnosis The diagnosis of viral hepatitis is confirmed by serologic testing
(1).
Treatment 1-The treatment of acute hepatitis
(1) (except HCV
(3)) is largely supportive and
involves rest, hydration, and adequate nutrition. Hospitalization is indicated for
severe cases (1)
.
2-Chronic HBV infection may be treated with interferon alfa-2b or
lamivudine, and HCV may be treated with interferon alfa usually in
combination with Ribavirin (1)
.
References 1-Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition.2015.
2-Nelson Textbook of pediatrics. 29th edition.
3-Edward T. Bope, et al, eds. Conn’s Current Therapy. Copyright 2014.
3-Wilson’s disease (1, 2)
1- Wilson’s disease is a rare autosomal recessive disorder leading to toxic
accumulation of copper in the liver and, subsequently, other tissues especially
the brain and eye..
Presentation • Kayser–Fleischer rings (copper deposition in the eye) • Hepatic problems usually present in childhood (hepatitis, cirrhosis,
fulminant hepatic failure).
• Adolescents/young adults usually present with neurological disease.
Diagnosis The diagnosis is made by identifying depressed serum levels of
ceruloplasmin, elevated 24-hour urine copper excretion, and the presence of
Kayser-Fleischer rings in the iris.
Treatment 1-Treatment consists of administration of copper-chelating drugs
(penicillimine) (reverses pre-cirrhotic liver disease, but not neurological
damage).
29
2-Zinc salts often replace chelating agents after chelation therapy has
successfully reduced excessive body copper stores.
3-Adequate therapy must be continued for life to prevent liver and CNS
deterioration.
References 1- Robert M. Kliegman. Nelson essentials of pediatrics. 7
th edition. 2015.
2- Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013
H-Respiratory Disorders 1-Cystic Fibrosis
Background
1-Cystic fibrosis (CF) is an autosomal recessive multisystem disorder caused by
mutations in the cystic fibrosis transmembrane regulator (CFTR) gene (1)
.
2- CFTR is important for the proper movement of salt and water across epithelial
cell membranes especially in the airways, liver, and pancreas (2)
. The term cystic
fibrosis arises from the fibrotic scar tissue that replaces the destroyed pancreas (3)
.
Pathophysiology
A-Pulmonary System 1-In CF, there are reduced chloride secretion with excessive sodium resorption
which lead to dehydration of the airway lining (4)
leading to airway obstruction.
This, in turn, leads to colonization with bacteria especially Staphylococcus
aureus and Pseudomonas aeruginosa (2)
.
2-Chronic lung disease is a hallmark of CF, leading to death in 90% of patients
(5). CF patients will usually experience chronic respiratory infections
(6).
B-Gastrointestinal Involvement 1- Approximately 10% of patients with CF are born with intestinal obstruction
caused by inspissated meconium (meconium ileus). In older patients, intestinal
obstruction may result from thick inspissated mucus in the intestinal lumen (2)
.
C-Hepatic Involvement 1-In patients with CF, there is reduction in water and sodium movement into the
bile. The resulting decrease in the volume and flow of bile leads to stasis and
obstruction of the biliary tree. With chronic obstruction, this leads to biliary
cirrhosis (3)
.
D-Pancreatic Involvement 1-The obstruction of the pancreatic ducts result in the inability to excrete
pancreatic enzymes into the intestine. This leads to malabsorption of proteins,
sugars (to a lesser extent), and especially fat. Fat malabsorption manifests
clinically as steatorrhea (large foul-smelling stools), deficiencies of fat-soluble
vitamins (A, D, E, and K), and failure to thrive (2)
.
30
E-Sweat Gland In the sweat duct, CFTR reabsorbs chloride from sweat. Dysfunctional CFTR
results in a nearly fivefold elevation in sweat chloride concentrations. This is
the principal laboratory criterion for diagnosis of CF ( sweat chloride test) (7)
.
Diagnosis CF is most commonly diagnosed on the basis of typical signs and symptoms
and an abnormal sweat chloride concentration (>60 mEq/L) ( sweat chloride
test) (3, 7)
.
Treatment The treatment of CF is multifactorial, but it is primarily directed toward the
gastrointestinal and pulmonary complications (2)
.
A-Gastrointestinal System 1-Pancreatic enzyme replacement (lipase, protease, and amylase) is the
mainstay of gastrointestinal therapy (5)
.
2-Fat-soluble vitamins (A, D, E, and K) supplementation is usually required
in pancreatic insufficiency (5)
.
3-The use of ursodeoxycholic acid (UDCA) may improves bile flow, prevent
obstruction and slow progression of liver disease (5, 7)
.
B-Treatment of Cystic Fibrosis Airway Disease Treatment of CF airway disease involves the use of medications and techniques
to mobilize pulmonary secretions, and antibiotics to manage infection (3)
.
1-Mucociliary Clearance
A-Physical Therapy: Airway clearance can be performed using various
techniques. These techniques are recommended on a daily basis to help
mobilize secretions (8)
.
B-Mucolytic Therapy: Sputum viscosity is increased by the large
quantities of extracellular DNA that result from chronic airway
inflammation and degradation of neutrophils (9)
. Inhaled recombinant
human deoxyribonuclease (rhDNase, dornase alpha) cleaves extracellular
DNA in sputum (9)
.
C-Airway Hydration Therapies : Inhalation of hypertonic saline
rehydrates the airways through osmotic flow of water (3)
.
D-Bronchodilators: β-Agonists keep airways open and facilitate airway
clearance (8)
.
31
2-Antibiotics 1-Antibiotics are used to treat lung infection. Typical regimens for severe
infections include an antipseudomonal β-lactam plus an aminoglycoside for
added synergy and delay of resistance development (5)
.
2-Fluoroquinolone use is common among CF patients infected with P.
aeruginosa, even in children (5)
.
3-Chronic maintenance antibiotic therapy may be used in patients with
Pseudomonas colonization in an attempt to prevent bacterial overgrowth (5)
.
Inhaled tobramycin has been studied the most extensively (5)
.
Pharmacokinetic Considerations CF patients have larger volumes of distribution of many antibiotics and also
have an enhanced total body clearance (5)
. As a result of these pharmacokinetic
changes, higher doses of antibiotics (e.g. aminoglycosides, and β-lactam
antibiotics) are needed (5)
.
Lung transplantation Lung transplantation is currently the only definitive treatment for advanced
cystic fibrosis (9)
.
Prognosis The longevity of patients with cystic fibrosis is increasing, and the median
survival age is over 35 years. Death occurs mostly from pulmonary
complications (9)
.
References 1-Thomas P. Green. Pediatrics Just the Facts. Copyright © 2005 by The McGraw-Hill Companies,
Inc.
2-Robert M. Kliegman. Nelson essentials of pediatrics. 7th edition.
3-Koda-Kimble and Young’s. Applied Therapeutics: The clinical use of drugs, 10th ed., 2013 by
Lippincott Williams & Wilkins.
4-Nicholas A. Boon, Nicki R. Colledge and Brian R. Walker. Davidson's Principles and Pracrtice of
Medicines . 21st Edition 2010.
5-Marie A. Chisholm-Burns .Pharmacotherapy Principles & Practice Copyright © 2008 by The
McGraw-Hill Companies
6-Joseph T. DiPiro, Robert L. Pharmacotherapy: A Pathophysiologic Approach, 8th Edition.
Copyright 2011.
7-David J Quan, Richard A Helms. Textbook of Therapeutics: Drug and Disease Management. 8th
edition.
8-Edward T. Bope, et al, eds. Conn’s Current Therapy. . Copyright 2013.
9-Maxine A. Papadakis, et al, eds. Current Medical Diagnosis & Treatment, 52nd
Edition 2013.
32
I-Endocrinology 1-Diabetic ketoacidosis (DKA) 1-Definition: Arterial pH <7.30, bicarbonate <15 meq/L, glucose >250 mg/dL,
and Urinary ketones (1, 2)
.
2-DKA is a major medical emergency and remains a serious cause of
morbidity, principally in people with type 1 diabetes (3)
(More common in
type 1 DM but can occur in type 2 DM) (4)
.
3-A significant number of newly diagnosed diabetic children present with
DKA. In children with known diabetes, DKA occurs in patient who omit insulin
doses or who do not successfully manage an intercurrent illness (3, 5)
.
Risk Factors 1-Omission of insulin is the most common precipitant of DKA
(6).
2-Infections, acute medical illnesses, and stress of recent surgical procedures
can contribute to the development of DKA (6)
.
Pathophysiology 1-The hyperglycaemia causes a profound osmotic diuresis leading to
dehydration, hyperosmolarity, and electrolyte loss, particularly of sodium and
potassium (3, 6)
.
2-Owing to increased lipolysis and decreased lipogenesis, free fatty acids are
converted to ketone bodies and lead to metabolic acidosis (6, 7)
.
3- Electrolyte abnormalities occur through a loss of electrolytes in the urine (7)
.
In addition, The resulting metabolic acidosis causes efflux of potassium from
cells, results in intracellular potassium depletion (3, 6)
.
Clinical Presentation 1-Patients with DKA present initially with polyuria, polydipsia, nausea, and
vomiting. Abdominal pain occurs frequently (7)
.
2-Respiratory compensation for acidosis results in tachypnea with deep
(Küssmaul) respirations. The fruity odor of acetone frequently can be
detected on the patient’s breath (7)
.
3-An altered mental status can occur, ranging from disorientation to coma (7)
.
Management 1-DKA is a medical emergency which should be treated in hospital
(3). The
principal components of treatment are :
• The administration of short-acting (soluble) insulin (3)
.
33
• Fluid replacement (initially with 0.9% sodium chloride) (3)
.
• Potassium replacement (3)
.
• The administration of antibiotics if infection is present (3)
.
Note: for more details about the management of ketoacidosis , there is a
Diabetic Ketoacidosis Treatment Protocol (5)
.
Complications The most concerning complication of DKA is cerebral oedema (Treatment by
Mannitol 1 g/kg IV) (2)
.
References 1-Thomas P. Green. Pediatrics Just the Facts. Copyright © 2005 by..
2-Robert C. Tasker. Oxford Handbook of Paediatrics. 2nd
edition.2013
3-Nicholas A. Boon, Nicki R. Colledge and Brian R. Walker. Davidson's Principles and
Pracrtice of Medicines . 21st Edition 2010.
4-ACCP Updates in Therapeutics® 2012: The Pharmacotherapy Preparatory Review and
Recertification Course. 5-Nelson Textbook of pediatrics. 29
th edition,
6-Edward T. Bope, et al, eds. Conn’s Current Therapy. Copyright 2014.
7-Robert M. Kliegman. Nelson essentials of pediatrics. 7th
edition.2015.
34
Some Pediatric Doses (to be filled by the student)
Drug Pediatric Dose
1
2
3
4
5
6
7
8
9
10